Topological Logarithmic Structures

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Earl Manning
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1 Department of Mathematics University of Oslo 25th Nordic and 1st British Nordic Congress of Mathematicians Oslo, June 2009

2 Outline 1 2 3

3 Outline Pre-log rings Pre-log S-algebras Repleteness 1 2 3

4 Pre-log rings Pre-log rings Pre-log S-algebras Repleteness Definition A pre-log ring is a commutative ring A and a commutative monoid M, with a ring homomorphism Z[M] A from the monoid ring of M to A. This is the affine form of a notion for schemes introduced by Fontaine, Illusie, Kato. Log geometry is useful to relate the special and generic fibers for schemes over e.g. Spec(Z p ).

5 Mild localization Pre-log rings Pre-log S-algebras Repleteness The pre-log ring (A, M) may be viewed as a less drastic localization of A than A[M 1 ], giving a geometric object intermediate between Spec(A) and Spec(A[M 1 ]): Spec(A[M 1 ]) Spec(A, M) Spec(A) Guiding Question: When does the first map induce an equivalence in de Rham cohomology, algebraic K -theory or other functors?

6 E ring spectra and E spaces Pre-log rings Pre-log S-algebras Repleteness For the topological theory, we replace commutative rings by some form of E ring spectra, and commutative monoids by some form of E spaces. In this talk, we model E ring spectra by commutative symmetric ring spectra [Hovey Shipley Smith]. We model E spaces by commutative I-space monoids [Bökstedt, Schlichtkrull]. For brevity, we often say S-algebra for symmetric ring spectrum.

7 Pre-log rings Pre-log S-algebras Repleteness Symmetric spectra and I-spaces A symmetric spectrum E in Sp Σ is a sequence of based Σ n -spaces E n for n 0, with structure maps σ: E n S 1 E n+1, such that σ m is Σ n Σ m -equivariant for all n, m 0. The category I has objects the finite sets n = {1,...,n} for n 0, and morphisms the injective functions. An I-space X in S I is a functor from I to spaces. There is an adjunction S[ ]: S I Sp Σ : Ω where S[X] = {n X(n) + S n }, and Ω (E): n Ω n E n.

8 Commutative monoids Pre-log rings Pre-log S-algebras Repleteness A commutative S-algebra A in CSp Σ is a commutative monoid S η µ A A A with respect to the smash product of symmetric spectra. A commutative I-space monoid M in CS I is a commutative monoid η µ 1 M M M with respect to the (convolution) product of I-spaces. (NB: Suppressing a comparison M M M M.) There is still an adjunction S[ ]: CS I CSp Σ : Ω

9 Pre-log S-algebras Pre-log rings Pre-log S-algebras Repleteness Definition A pre-log S-algebra (A, M) is a commutative S-algebra A and a commutative I-space monoid M, with an S-algebra map S[M] A from the spherical monoid ring of M to A. When M = 1 we get the trivial pre-log S-algebra (A, 1). When A = S[M], we get the canonical pre-log S-algebra (S[M], M). A map (A, M) (B, N) consists of an S-algebra map A B and an I-space monoid map M N, so that the two composite maps S[M] B agree.

10 Two building blocks Pre-log rings Pre-log S-algebras Repleteness Any pre-log S-algebra (A, M) is a pushout of trivial and canonical pre-log S-algebras: (S[M], 1) (S[M], M) (A, 1) (A, M) In this sense any pre-log scheme is locally a fiber product of ordinary schemes like Spec(A) and canonical pre-log schemes like Spec(S[M], M).

11 Integral, saturated, Kummer Pre-log rings Pre-log S-algebras Repleteness In deformation theory of pre-log schemes, one works with commutative monoids M satisfying the following conditions: M is finitely generated. The group completion map γ : M M gp is injective. If x M gp and x n M for some n 1 then x M. In the theory of log-étale descent, one works with injective monoid homomorphisms M N with a constant k such that x k M for all x N. These properties have no clear topological analog.

12 Replete homomorphisms Pre-log rings Pre-log S-algebras Repleteness Their main use is to ensure that certain homomorphisms ǫ: N M are replete, in the sense that ǫ gp : N gp M gp is surjective, and N γ N gp is a pullback square. ǫ M ǫ gp γ M gp In other words, N M is virtually surjective and exact. We propose to emphasize these properties instead.

13 Group completion and units Pre-log rings Pre-log S-algebras Repleteness The full embedding (CS I ) gp CS I of grouplike objects among all commutative I-space monoids has a left adjoint (group completion) Γ = ( ) gp : CS I (CS I ) gp and a right adjoint (homotopy units) F = ( ) : CS I (CS I ) gp.

14 Replete maps Pre-log rings Pre-log S-algebras Repleteness Definition Let ǫ: N M be a map of commutative I-space monoids. We say that N is replete over the base M if π 0 (Γǫ): π 0 (N) gp π 0 (M) gp is surjective, and the square is a homotopy pullback. N γ ΓN ǫ Γǫ M γ ΓM The surjectivity condition is automatic if ǫ has a section η: M N, so that N is an object under and over M.

15 Pre-log rings Pre-log S-algebras Repleteness Repletion of commutative I-space monoids Definition For a given ǫ: N M with π 0 (Γǫ) surjective, the repletion N rep of N over M is defined by the right hand homotopy pullback square: N ΓN Lemma N rep is replete over M. ǫ N rep M = M γ ΓM One proof uses the Bousfield Friedlander theorem. Γǫ

16 The shear map Pre-log rings Pre-log S-algebras Repleteness Let M be a base commutative I-space monoid, and consider M η M M µ M as an object under and over M, where µ(x, y) = xy is the multiplication map, and η(x) = (x, 1) is the left unit. Lemma The repletion of µ: M M M is pr 1 : M ΓM M, via the shear map sh: M M M ΓM with sh(x, y) = (xy, γ(y)).

17 Proof Pre-log rings Pre-log S-algebras Repleteness M M sh µ M ΓM γ ΓM ΓM ΓM ΓM µ (x, y) (xy, y) so M pr 1 = γ M pr 1 ΓM (M M) rep = M ΓM. xy

18 Repletion of pre-log S-algebras Pre-log rings Pre-log S-algebras Repleteness Definition Let (B, N) (A, M) be a map of pre-log S-algebras. We say that (B, N) is replete over the base (A, M) if N is replete over M. For a given map (B, N) (A, M) with π 0 (N) gp π 0 (M) gp surjective, the repletion of (B, N) over the base (A, M) is (B, N) rep = (B rep, N rep ), where B rep = B S[N] S[N rep ]. The surjectivity condition is automatic if (B, N) is an object under and over (A, M).

19 Outline Subcategories of replete objects Log topological Hochschild homology Log topological cyclic homology 1 2 3

20 Reflective subcategories Subcategories of replete objects Log topological Hochschild homology Log topological cyclic homology The full subcategories of replete objects (M/CS I /M) rep (M/CS I /M) ((A, M)/PreLog/(A, M)) rep (A, M)/PreLog/(A, M) in commutative I-space monoids under and over M M η N ǫ M, resp. in pre-log S-algebras under and over (A, M) (A, M) η (B, N) ǫ (A, M), are reflective, meaning that repletion ( ) rep is left adjoint to the forgetful functor.

21 Topological log geometry Subcategories of replete objects Log topological Hochschild homology Log topological cyclic homology To do topological log geometry relative to a base (pre-)log S-algebra (A, M), we propose to work in the category ((A, M)/PreLog/(A, M)) rep of replete pre-log S-algebras (B, N) under and over (A, M). Limits are formed as for pre-log S-algebras over (A, M). Colimits are formed by applying repletion to the colimit for pre-log S-algebras under (A, M). This category is pointed at (A, M).

22 Tensored structure Subcategories of replete objects Log topological Hochschild homology Log topological cyclic homology For (B, N) in (A, M)/PreLog/(A, M) and Y a pointed set, Here Y (A,M) (B, N) = (Y A B, Y M N) Y A B = A B (B A A B) Y M N = M N (N M M N) with one copy of B, resp. N, for each element of Y. For Y a pointed simplicial set, Y (A,M) (B, N) is the realization of [q] Y q (A,M) (B, N).

23 Cyclic bar construction, THH Subcategories of replete objects Log topological Hochschild homology Log topological cyclic homology Lemma The suspension of M M in (M/CS I /M) is the cyclic bar construction B cy (M) = S 1 M (M M). It equals the unreduced tensor S 1 M in CS I. Lemma The suspension of A A in (A/CSp Σ /A) is the topological Hochschild homology THH(A) = S 1 A (A A). It equals the unreduced tensor S 1 A in CSp Σ.

24 Replete bar construction Subcategories of replete objects Log topological Hochschild homology Log topological cyclic homology We are interested in the replete versions. Definition The replete bar construction is the repletion B rep (M) = (B cy (M)) rep over M of the cyclic bar construction. It equals the suspension B rep (M) = S 1 M (M ΓM) of (M ΓM, pr 1 ) in (M/CS I /M) rep.

25 The suspended shear map Subcategories of replete objects Log topological Hochschild homology Log topological cyclic homology Lemma B rep (M) = M B(ΓM) where B(N) = S 1 1 N is the usual bar construction. The repletion map B cy M B rep (M) is the suspended shear map S 1 M sh. It factors as B cy (M) B cy (M) B cy (M) ǫ π M B(M) id γ M B(ΓM)

26 Log THH Subcategories of replete objects Log topological Hochschild homology Log topological cyclic homology Definition The log topological Hochschild homology is the repletion over (A, M). (THH(A, M), B rep (M)) = (THH(A), B cy (M)) rep It equals the suspension (S 1 (A,M) (A A, M M)) rep of (A A, M M) in ((A, M)/PreLog/(A, M)) rep, and the unreduced tensor (S 1 (A, M)) rep of (A, M) in (PreLog/(A, M)) rep.

27 A pushout square Subcategories of replete objects Log topological Hochschild homology Log topological cyclic homology Theorem There is a homotopy pushout square S[B cy (M)] ψ S[B rep (M)] of commutative S-algebras. φ THH(A) THH(A, M) Here φ is induced by S[M] A, and ψ is induced by the suspension of the shear map.

28 A rewritten pushout square Subcategories of replete objects Log topological Hochschild homology Log topological cyclic homology Corollary There is a homotopy pushout square THH(S[M]) ψ THH(S[M], M) of commutative S-algebras. φ THH(A) THH(A, M) Hence log THH is determined by ordinary THH and its value THH(S[M], M) = S[B rep (M)] on canonical pre-log S-algebras.

29 Subcategories of replete objects Log topological Hochschild homology Log topological cyclic homology The Hesselholt Madsen construction Let K by a local field of characteristic 0, with perfect residue field k of characteristic p 2, valuation ring A, and uniformizer π A. Let M = {π j j 0}, with the obvious map S[M] HA to the Eilenberg Mac Lane spectrum. In this case, Hesselholt Madsen define a cyclotomic spectrum THH(A K) with a homotopy cofiber sequence THH(k) i THH(A) j THH(A K) such that e.g. π 1 THH(A K) = Ω 1 (A,M) is the A-module of log Kähler differentials.

30 A comparison result Subcategories of replete objects Log topological Hochschild homology Log topological cyclic homology Theorem Suppose that K is wildly ramified, so that the ramification index e of (π) over (p) is divisible by p. Then there is an isomorphism of Z/p-algebras. Conjecturally, π (THH(A K); Z/p) = π (THH(HA, M); Z/p) THH(A K) THH(A, M) also in the unramified and tamely ramified cases.

31 Cyclic structure Subcategories of replete objects Log topological Hochschild homology Log topological cyclic homology The replete bar construction inherits a cyclic structure [Connes] from the pullback square in CS I B rep (M) M γ B cy (ΓM) ǫ ΓM Log THH gets a cyclic structure from the pushout square S[B cy (M)] ψ S[B rep (M)] φ THH(A) THH(A, M) in CSp Σ.

32 Subcategories of replete objects Log topological Hochschild homology Log topological cyclic homology Cyclotomic structure (work in progress) If for each r N the square M γ ΓM x is homotopy cartesian, then ( ) r ( ) r M γ ΓM x r B rep (M) Cr = B rep (M) and THH(S[M], M) = S[B rep (M)] is a cyclotomic spectrum [Hesselholt Madsen].

33 Log topological cyclic homology Subcategories of replete objects Log topological Hochschild homology Log topological cyclic homology Assuming this, the log topological cyclic homology TC(S[M], M) is defined. The cyclotomic structures on THH(A), THH(S[M]) = S[B cy (M)] and THH(S[M], M) = S[B rep (M)] determine a cyclotomic structure on THH(A, M) = THH(A) S[B cy (M)] S[B rep (M)]. This gives a general definition of TC(A, M). When is it close to K(A[M 1 ])?

34 An example for log THH Subcategories of replete objects Log topological Hochschild homology Log topological cyclic homology Lemma Let M = {x j j 0}. We have (finite in) S 1 -equivariant equivalences B cy (M) j 1 B rep (M) j 0 S 1 (j) L >0 S 1 S 1 (j) L 0 S 1 B cy (ΓM) j Z S 1 (j) LS 1.

35 An example for log TC Subcategories of replete objects Log topological Hochschild homology Log topological cyclic homology Theorem Let M = {x j j 0}. There is a homotopy pullback square TC(S[M], M) α ΣS[L 0 S 1 S 1 ES 1 ] β S[L 0 S 1 ] trf S 1 1 p S[L 0 S 1 ] after p-adic completion. Same proof as in [Bökstedt Hsiang Madsen].

36 Localization sequences Subcategories of replete objects Log topological Hochschild homology Log topological cyclic homology Corollary Let M = {x j j 0}. There are homotopy cofiber sequences and THH(S) TC(S) i THH(S[M]) i TC(S[M]) j THH(S[M], M) j TC(S[M], M). Should be compared with the fundamental theorem for A-theory [Hüttemann Klein Vogell Waldhausen Williams].

37 Outline Log topological André Quillen homology Log modules Non-connective extensions 1 2 3

38 Log topological André Quillen homology Log modules Non-connective extensions Stable commutative augmented A-algebras Suspension B E(B) = S 1 A B defines an endofunctor on A/CSp Σ /A. By an E-spectrum in A/CSp Σ /A we mean a sequence {n B n } of commutative augmented A-algebras, with structure maps σ: E(B n ) B n+1. The category of E-spectra in A/CSp Σ /A is equivalent to the category of A-modules, taking {n B n } to hocolim n Σ n (B n /A). [Basterra Mandell]

39 Log topological André Quillen homology Log modules Non-connective extensions Topological André Quillen homology Definition The topological André Quillen homology of A is the A-module TAQ(A) that corresponds to the suspension spectrum of A A in A/CSp Σ /A. E (A A) = {n S n A (A A)}

40 Stable repletion Log topological André Quillen homology Log modules Non-connective extensions The n-fold suspension of the shear map S n M sh: S n M (M M, µ) S n M (M ΓM, pr 1 ) = M B n (ΓM) expresses the repletion of S n M (M M) as M B n (ΓM). The sequence B M = {n B n (ΓM)} is the connective spectrum associated to the commutative I-space monoid M, or equivalently, to ΓM.

41 Log TAQ Log topological André Quillen homology Log modules Non-connective extensions Definition The log topological André Quillen homology of (A, M) is the A-module TAQ(A, M) that corresponds to the levelwise repletion {n (S n (A,M) (A A, M M)) rep } of the suspension spectrum of (A A, M M) in (A, M)/PreLog/(A, M). In other words, this is the suspension spectrum of (A A, M M) in ((A, M)/PreLog/(A, M)) rep.

42 A pushout square Log topological André Quillen homology Log modules Non-connective extensions Theorem There is a homotopy pushout square A S[M] TAQ(S[M]) ψ A B M φ TAQ(A) TAQ(A, M) of A-modules. Here φ is induced by S[M] A, and ψ is induced from the infinite suspension of the shear map.

43 Log derivations Log topological André Quillen homology Log modules Non-connective extensions Lemma For each A-module K there is an equivalence (A Mod)(TAQ(A, M), K) Der((A, M), K) between the space of A-module maps TAQ(A, M) K and the space of log derivations of (A, M) with values in K. In other words, TAQ(A, M) properly plays the role of log Kähler differentials.

44 Log modules Log topological André Quillen homology Log modules Non-connective extensions There does not appear to be a classical notion of modules over a pre-log ring. We propose: Definition Let the category (A, M) Mod = Sp(((A, M)/PreLog/(A, M)) rep, E) of log modules over (A, M) be the stable category of E-spectra in replete pre-log S-algebras under and over (A, M). Then TAQ(A, M) is a natural example of a log module.

45 Log K -theory (work in progress) Log topological André Quillen homology Log modules Non-connective extensions Definition Let the log K -theory of (A, M) be the algebraic K -theory K(A, M) = K((A, M) Perf) of the category of perfect (= compact) objects in (A, M) Mod. There is a natural localization map K(A, M) K(A[M 1 ]). When is it an equivalence? There seems to be a natural trace map tr : K(A, M) THH(A, M). Does it lift through TC(A, M)?

46 Log topological André Quillen homology Log modules Non-connective extensions Non-connective E spaces (work in progress) For connective M, the structure map S[M] A only touches the connective cover of A. There is a category J = Σ 1 Σ, extending I, so that commutative J-space monoids have underlying commutative I-spaces monoids [Sagave Schlichtkrull]. Just as grouplike commutative I-space monoids are equivalent to connective spectra Sp 0 (CS I ) gp CS I, it appears that a full subcategory of commutative J-space monoids is equivalent to all spectra Sp (CS J ) gp CS J.

47 Direct image structures Log topological André Quillen homology Log modules Non-connective extensions In the Hesselholt Madsen example i : A K, the appropriate log structure on A is M = i GL 1 (K), the direct image of the trivial log structure on K. With this log structure they prove that K(K) TC(A K) is a p-adic equivalence except in low degrees. For a periodic spectrum E with connective cover i : e E, the appropriate (pre-)log structure on e may be M = i GL J 1 (E), where GLJ 1 (E) is constructed as a grouplike commutative J-space monoid. When will K(E) TC(e, M) be a p-adic equivalence with this structure? For example, we may consider E = KU p and e = ku p.

arxiv: v2 [math.at] 18 Sep 2008

arxiv: v2 [math.at] 18 Sep 2008 TOPOLOGICAL HOCHSCHILD AND CYCLIC HOMOLOGY FOR DIFFERENTIAL GRADED CATEGORIES arxiv:0804.2791v2 [math.at] 18 Sep 2008 GONÇALO TABUADA Abstract. We define a topological Hochschild (THH) and cyclic (TC)